Description

Background :

Hypertension remains the most prevalent modifiable risk factor associated with cardiovascular morbidity and mortality, however un-optimally treated hypertension prevalence remains alarmingly high. Variable blood pressure response to pharmacological treatment, physician inertia and lack of patient's compliance due to polypharmacy, are the main reasons behind non optimal blood pressure treatment. The multifactorial nature of hypertension has long been described, with various environmental, genetic and epi-genetic factors involved in its pathogenesis and progression. Therefore, scientific interest is starting to shift towards precision medicine, as a medical model for disease prevention and tailored treatment that incorporates individual, genetic, environmental and experiential variability. Το this end, proteomic analysis is an emerging representative in the research of predictive biomarkers.

Proteomic analysis consists of the qualitive and quantitative analysis of the final proteins in bodily fluids. A simplified approach constitutes of sample acquisition, protein extraction and separation through high-resolution electrophoresis and chromatography-based techniques, protein sequence determination with mass spectrometry-based analysis and protein identification with bioinformatic techniques in referential databases. Various small scale clinical trials have highlighted the clinical significance if proteomic analysis, ranging from identifying biomarkers able to determine the blood pressure response following treatment with spironolactone in patients with resistant hypertension, predicting pre-eclampsia through the urinary proteome even in early stages of gestation.

Obesity and essential hypertension are two pathological entities that often coexist. Data from the Framingham study suggesting a twofold risk of obese patients developing hypertension compared to underweight ones, while similar associations have been described by the NHANES III, MONICA, and Health, Aging and Body Composition Study studies, between increases in blood pressure, as a result of increases in BMI, waist circumference, and visceral fat, respectively. The mechanisms through which obesity leads to the development of hypertension, are a complex pathophysiological phenomenon under constant research and study, including the activation of the Sympathetic Nervous System, disorder of renal sodium excretion, excessive renin-angiotensin-aldosterone axis activation and endothelial dysfunction. Angiotensin 2 receptor blockers like Irbesartan, have long been used as first-line pharmacological treatment, however clinical trials including ASPIRANT, PATHWAY-2, and RALES study, have highlighted the role of aldosterone receptor blockers in obese hypertensive patients. Spironolactone and eplerenone are the main oral representatives of this group, with the latter showing less frequent side effects as well as higher binding specificity for the mineralocorticoid- receptor.

Aim of the study:

The main purpose of this study is to investigate the potential predictive role of urinary proteomics, in blood pressure response of obese hypertensive patients, after treatment with irbesartan or eplerenone. This hypothesis may lead to the emergence of urinary biomarkers able to predict blood pressure response in obese hypertensive patients.

Study design:

In this interventional study, untreated obese hypertensive patients will be randomized to two pharmacological treatment arms. Blood pressure response will be assessed based on a baseline visit prior to the initiation of pharmacological treatment and a follow-up visit after an 8-week interval. Patients will be categorized as either responders or non-responders based on the changes in their blood pressure levels. The analysis of patients' baseline urinary samples will be conducted using Liquid Chromatography with tandem mass spectrometry (LC-MS/MS). The examination of individual urinary peptides, along with the evaluation of blood pressure response, will be employed to pinpoint distinct urinary proteins that can act as indicators predicting the response to blood pressure alterations after pharmacological treatment.

Methods

A total of 50 untreated obese hypertensive adults, will be randomized to irbesartan 150mg once daily, or eplerenone 25mg twice daily.

Patients will undergo a detailed medical history questionnaire and clinical-laboratory examination, in order to ensure that the inclusion and exclusion criteria are met. For inclusion in the study, signed informed consent will be required, after detailed briefing on the study procedure and objectives, as well as potential risks. Ethics approval has been obtained from the hospital's ethical committee board.

Baseline blood pressure levels will be determined with ambulatory blood pressure measurement (ABPM), office blood pressure measurement (OBP) and home blood pressure measurement (HBP). Before treatment initiation, a urinary sample will be collected and stored under appropriate conditions, until subjected to proteomic analysis. Patient data will be recorded anonymously in an electronic database, through which randomization of patients will be carried out. Following randomization, medication stored appropriately on-site, will be administered to each patient.

The participants will undergo a follow-up visit after 8 weeks, where blood pressure response will be determined with ABPM, OBP and HBP. Adherence to treatment will be determined though a medication diary, provided at baseline visit. Patients with ≥ 5mmHg reduction in systolic mean ABPM and/or ≥10mmHg systolic OBP reduction will be considered responders to the corresponding treatment.

Stored urinary samples will undergo liquid chromatography with tandem mass spectrometry (LC-MS/MS) analysis. Data will be processed and cross-referenced with bioinformatics software and databases for protein identification. To establish the certainty of the protein identification false discovery rate (FDR) validation will be based on q value, with target FDR: 0.05. Peptide distribution of intensity between responders and non responders will be assessed, to establish differential expression in each arm. Differential expression will be measured in fold change, as the relative difference in protein abundance between the two conditions. Student's t-test or Mann Whitney non-parametric test will be used.